Difference between revisions of "Silo"

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'''Silo''' is a newly developed robot, engineered using advanced reinforcement learning and deep learning techniques.
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'''Silo''' represents the forefront of robocode engineering, being meticulously crafted using cutting-edge reinforcement learning and deep learning methodologies. It is presently in the throes of active development.
  
 
=== Vision ===
 
=== Vision ===
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* A cohesive teacher network adept at learning targeting, wave surfing, and energy management in an end-to-end manner.
 
* A cohesive teacher network adept at learning targeting, wave surfing, and energy management in an end-to-end manner.
 
* Multiple compact networks designed to distill the knowledge acquired and unearthed by the teacher network, ideal for environments with constrained computational resources.
 
* Multiple compact networks designed to distill the knowledge acquired and unearthed by the teacher network, ideal for environments with constrained computational resources.
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{{Template:Bot Categorizer|author=Xor|isMega=true|isOneOnOne=true|isMelee=false|isOpenSource=false|extends=Interface}}

Revision as of 16:18, 10 January 2024

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Silo
Author(s) Xor
Extends AdvancedRobot

Silo represents the forefront of robocode engineering, being meticulously crafted using cutting-edge reinforcement learning and deep learning methodologies. It is presently in the throes of active development.

Vision

Hand-crafted strategies have their merits, but algorithms that dynamically adapt to evolving distributions are superior. The ultimate objective of Silo is to develop a suite of self-evolving algorithms, capable of outperforming all competitors through continual data updates alone.

Development

The development of Silo unfolds in two interdependent parts, evolving in tandem.

Frameworks

  • An advanced robot development framework designed for automated testing and experimentation, which ultimately progresses to self-programming capabilities.
  • A comprehensive framework for robot data collection, processing, and model training, tailored specifically for deep reinforcement learning techniques. This integrated system allows for optimization and evaluation of every component within a unified platform.

Models

  • A cohesive teacher network adept at learning targeting, wave surfing, and energy management in an end-to-end manner.
  • Multiple compact networks designed to distill the knowledge acquired and unearthed by the teacher network, ideal for environments with constrained computational resources.